Intelligent port control system and related systems and apparatuses

ABSTRACT

An example intelligent port control system may include a scheduling center system configured to generate a ship unloading plan, generate a ship berthing task and a ship unloading task based on the ship unloading plan, and transmit the ship berthing task and the ship unloading task to a ship control system of a target ship and a shore crane control system of a target shore crane apparatus, respectively. The ship control system may be configured to transmit the ship information and the container information to the scheduling center system, and control the target ship to move to an operation area corresponding to the target shore crane apparatus. The shore crane control system may be configured to control the target shore crane apparatus to load the container on the target ship onto a transportation vehicle in accordance with the ship unloading task.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent document is a divisional of U.S. patent application Ser. No. 16/677,359, filed on Nov. 7, 2019, which claims priority to and the benefit of Chinese Patent Application No. 201811321218.1, filed on Nov. 7, 2018. The aforementioned applications are incorporated herein by reference in their entireties.

TECHNICAL FIELD

The present disclosure relates to intelligent control technology, and more particularly, to an intelligent port control system and related systems and apparatuses.

BACKGROUND

As a hub station for waterway-land coordinated transportation, a port is a buffer for conversion of transportation schemes of containerized goods, and plays an important role in the whole container transportation process. At the port, container transportation operations such as container unloading and container loading are required for inbound and outbound containers.

The process of container unloading is generally as follows. After a ship arrives at a port, a container is first moved onto a transportation vehicle by a shore crane (or shore bridge). Then, the container is transported by the transport vehicle to a yard (or warehouse center). Finally, the container on the transportation vehicle is placed at a corresponding location in the yard by a warehouse hoisting apparatus (such as a rail-mounted gantry crane, a rubber-tired gantry crane, a forklift, etc.) near the yard, thereby completing the ship unloading operation.

The process of container loading is generally as follows. A container in a yard is lifted and placed onto a transportation vehicle by a warehouse hoisting apparatus at the yard, and transported by the transportation vehicle to a shore crane where a ship is located. The container on the transportation vehicle is placed onto the ship by the shore crane, thereby completing the ship loading operation.

SUMMARY

In an aspect, an intelligent port control system is provided according to an embodiment of the present disclosure. The intelligent port control system includes: a scheduling center system configured to generate a ship unloading plan based on ship information and container information of a target ship and shore crane apparatus information, generate a ship berthing task and a ship unloading task based on the ship unloading plan, and transmit the ship berthing task and the ship unloading task to a ship control system of the target ship and a shore crane control system of a target shore crane apparatus, respectively; the ship control system configured to transmit the ship information and the container information to the scheduling center system, control the target ship to move to an operation area corresponding to the target shore crane apparatus in accordance with the received ship berthing task, and transmit a ship in-position notification message to the shore crane control system of the target shore crane apparatus; the shore crane control system configured to control, upon receiving the ship in-position notification message from the ship control system, the target shore crane apparatus to load the container on the target ship onto a transportation vehicle in accordance with the ship unloading task; a warehouse management system configured to assign, upon receiving a container storage task, a warehouse hoisting apparatus to hoist each target container carried by the transportation vehicle to a corresponding storage location in accordance with the container storage task; and a vehicle control system configured to control, upon receiving a container loading task, the transportation vehicle to move to a container loading location associated with the container loading task for loading the container, and to control, upon receiving a container unloading task, the transportation vehicle to move to a container unloading location associated with the container unloading task for unloading the container.

In another aspect, a scheduling center system is provided according to an embodiment of the present disclosure. The scheduling center system includes at least one machine executable instruction. The at least one machine executable instruction includes a scheduling communication module, a plan generation module and a task generation module. The at least one machine executable instruction is executed by a processor such that: the scheduling communication module is configured to transmit and receive information, the plan generation module is configured to generate a ship unloading plan based on ship information and container information of a target ship and shore crane apparatus information as received by the scheduling communication module, and the task generation module is configured to generate a ship berthing task and a ship unloading task based on the ship unloading plan, and transmit the ship berthing task and the ship unloading task to a ship control system of the target ship and a shore crane control system of a target shore crane apparatus, respectively, via the scheduling communication module.

In another aspect, a scheduling center system is provided according to an embodiment of the present disclosure. The scheduling center system includes at least one processor and at least one memory. The at least one memory stores the above scheduling center system executable by the at least one processor.

In another aspect, a ship control system is provided. The ship control system includes at least one machine executable instruction. The at least one machine executable instruction includes a ship communication module and a ship control module. The at least one machine executable instruction is executed by a processor such that: the ship communication module is configured to transmit and receive information, and the ship control module is configured to transmit ship information and container information to a scheduling center system via the ship communication module, and upon receiving a ship berthing task from the scheduling center system via the ship communication module, control a target ship to move to an operation area corresponding to a target shore crane apparatus, and transmit a ship in-position notification message to a shore crane control system of the target shore crane apparatus via the ship communication module.

In another aspect, a ship system is provided according to an embodiment of the present disclosure. The ship system includes at least one processor and at least one memory. The at least one memory stores the above ship control system executable by the at least one processor.

In another aspect, a ship is provided according to an embodiment of the present disclosure. The ship includes the above ship control system.

In another aspect, a shore crane control system is provided. The shore crane control system includes at least one machine executable instruction. The at least one machine executable instruction includes a shore crane communication module and a hoisting control module. The at least one machine executable instruction is executed by a processor such that: the shore crane communication module is configured to transmit and receive information, and the hoisting control module is configured to receive a ship unloading task from a scheduling center system via the shore crane communication module, and upon receiving a ship in-position notification message from a ship control system via the shore crane communication module, control a target shore crane apparatus to load a container on a target ship onto a transportation vehicle in accordance with the ship unloading task.

In another aspect, a shore crane control system is provided according to an embodiment of the present disclosure. The shore crane control system includes at least one processor and at least one memory. The at least one memory stores the above shore crane control system executable by the at least one processor.

In another aspect, a shore crane apparatus is provided according to an embodiment of the present disclosure. The shore crane apparatus includes the above shore crane control system.

In another aspect, a vehicle control system is provided according to an embodiment of the present disclosure. The vehicle control system includes at least one machine executable instruction. The at least one machine executable instruction includes a vehicle communication module and a vehicle control module. The at least one machine executable instruction is executed by a processor such that: the vehicle communication module is configured to transmit and receive information, and the vehicle control module is configured to control, upon receiving a container loading task via the vehicle communication module, a transportation vehicle to move to a container loading location associated with the container loading task for loading a container in accordance with the container loading task, and to control, upon receiving a container unloading task via the vehicle communication module, the transportation vehicle to move to a container unloading location associated with the container unloading task for unloading a container in accordance with the container unloading task.

In another aspect, a vehicle control system is provided according to an embodiment of the present disclosure. The vehicle control system includes at least one processor and at least one memory. The at least one memory stores the above vehicle control system executable by the at least one processor.

In another aspect, a transportation vehicle is provided according to an embodiment of the present disclosure. The transportation vehicle includes the above vehicle control system.

In another aspect, a warehouse management system is provided according to an embodiment of the present disclosure. The warehouse management system includes at least one machine executable instruction. The at least one machine executable instruction includes a warehouse communication module and a warehouse management module. The at least one machine executable instruction is executed by a processor such that: the warehouse communication module is configured to transmit and receive information, and the warehouse management module is configured to assign, upon receiving a container storage task via the warehouse communication module, a warehouse hoisting apparatus to hoist each target container carried by a transportation vehicle to a corresponding storage location in accordance with the container storage task.

In another aspect, a warehouse management system is provided according to an embodiment of the present disclosure. The warehouse management system includes at least one processor and at least one memory. The at least one memory stores the above warehouse management system executable by the at least one processor.

The other features and advantages of the present disclosure will be explained in the following description, and will become apparent partly from the description or be understood by implementing the present disclosure. The objects and other advantages of the present disclosure can be achieved and obtained from the structures specifically illustrated in the written description, claims and figures.

In the following, the solutions according to the present disclosure will be described in further detail with reference to the figures and embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

The figures are provided for facilitating further understanding of the present disclosure. The figures constitute a portion of the description and can be used in combination with the embodiments of the present disclosure to interpret, rather than limiting, the present disclosure. In the figures:

FIG. 1 is a schematic diagram showing a structure of an intelligent port control system according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram showing a structure of a scheduling center system according to an embodiment of the present disclosure;

FIG. 3 is a schematic diagram showing a structure of a ship control system according to an embodiment of the present disclosure;

FIG. 4 is a first schematic diagram showing a structure of a shore crane control system according to an embodiment of the present disclosure;

FIG. 5 is a second schematic diagram showing a structure of a shore crane control system according to an embodiment of the present disclosure;

FIG. 6 is a schematic diagram showing a structure of a vehicle control system according to an embodiment of the present disclosure; and

FIG. 7 is a schematic diagram showing a structure of a warehouse management system according to an embodiment of the present disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENTS

In the following, exemplary embodiments of the present disclosure will be described in further detail with reference to the figures. While the exemplary embodiments of the present disclosure are shown in the figures, it is to be noted that the present disclosure can be implemented in various forms and are not limited to the embodiments described below. Rather, these embodiments are provided to facilitate a more thorough understanding of the present disclosure and to convey the scope of the present disclosure fully to those skilled in the art.

Conventionally at a port, container transportation operations such as loading and unloading require human intervention. For example, ships need to be steered and controlled by humans to berth at specified locations. Hoisting apparatus and transportation vehicles need to be driven and operated by operators to perform operations such as container loading, container unloading and transportation. Yards or warehouse centers also need human intervention to arrange locations at which containers are to be placed. Thus, the conventional container transportation operations at the port have low level of intelligence and require a large amount of human resources, resulting in a low operation efficiency. Further, due to the complicated environment in the field, it is difficult to guarantee the safety of the operators. Moreover, the labor cost is relatively high as a large number of operators are required.

An intelligent port control system is provided according to an embodiment of the present disclosure. Referring to FIG. 1 , the intelligent port control system includes a scheduling center system 1, a ship control system 2 provided at a ship, a shore crane control system 3 provided at a shore crane apparatus, a warehouse management system 5 provided at a warehouse center, and a vehicle control system 4 provided at a transportation vehicle.

The scheduling center system 1 is configured to generate a ship unloading plan based on ship information and container information of a target ship and shore crane apparatus information, generate a ship berthing task and a ship unloading task based on the ship unloading plan, and transmit the ship berthing task and the ship unloading task to the ship control system 2 of the target ship and the shore crane control system 3 of a target shore crane apparatus, respectively (i.e., the scheduling center system 1 transmits the ship berthing task to the ship control system 2 of the target ship and transmits the ship unloading task to the shore crane control system 3 of the target shore crane apparatus).

The ship control system 2 is configured to transmit the ship information and the container information to the scheduling center system 1, control the target ship to move to an operation area corresponding to the target shore crane apparatus in accordance with the received ship berthing task, and transmit a ship in-position notification message to the shore crane control system 3 of the target shore crane apparatus.

The shore crane control system 3 is configured to control, upon receiving the ship in-position notification message from the ship control system 2, the target shore crane apparatus to load the container on the target ship onto a transportation vehicle in accordance with the ship unloading task.

The warehouse management system 5 is configured to assign, upon receiving a container storage task, a warehouse hoisting apparatus to hoist each target container carried by the transportation vehicle to a corresponding storage location in accordance with the container storage task.

The vehicle control system 4 is configured to control, upon receiving a container loading task, the transportation vehicle to move to a container loading location associated with the container loading task for loading the container, and to control, upon receiving a container unloading task, the transportation vehicle to move to a container unloading location associated with the container unloading task for unloading the container.

In some optional embodiments, the ship information may include ship arrival time and ship state information. The shore crane apparatus information may include operation time information of each shore crane apparatus in a port area. The container information may include a number of containers and identification information and a type of goods carried by each container. The ship information and the container information can be transmitted from the ship control system 2 of the target ship to the scheduling center system 1. The shore crane apparatus information may be information pre-stored in the scheduling center system 1. Alternatively, each shore crane apparatus in the port area can transmit its own shore crane apparatus information to the scheduling center system 1.

The scheduling center system 1 generating the ship unloading plan based on the ship information and container information of the target ship and the shore crane apparatus information may include: determining the target shore crane apparatus based on the ship arrival time and the operation time information of each shore crane apparatus in the shore crane apparatus information; estimating ship unloading start time and ship unloading end time based on the ship arrival time, the operation time information of the target shore crane apparatus and the number of containers, and determining a target container area for each container based on the type of goods carried by the container and information on container areas in the port area; and generating the ship unloading plan containing identification information of the target ship, identification information of the target shore crane apparatus, the ship unloading start time, the ship unloading end time and the identification information and the target container area for each container.

In an optional embodiment, the ship unloading start time can be determined by: determining whether the target shore crane apparatus is in an idle state at the ship arrival time based on the operation time of the target shore crane apparatus; and if so, determining the ship arrival time or the time at which the ship has arrived and berthed as the ship unloading start time, or otherwise determining the time at which the target shore crane apparatus completes the task it is performing at the ship arrival time as the ship unloading start time.

In an optional embodiment, the ship unloading end time can be determined by: calculating a time length required for the target shore crane apparatus to unload all containers on the target ship to be unloaded at the port based on a historical operation rate of the target shore crane apparatus; and obtaining the ship unloading end time based on the ship unloading start time and the time length.

As an optional implementation of the embodiment of the present disclosure, the scheduling center system 1 determining the target shore crane apparatus based on the ship arrival time and the operation time information of each shore crane apparatus in the shore crane apparatus information may include: determining one or more shore crane apparatuses available at the ship arrival time based on the ship arrival time and the operation time information of each shore crane apparatus; and selecting one of the determined one or more shore crane apparatuses as the target shore crane apparatus. The available shore crane apparatus may refer to a shore crane apparatus that is in an idle state at the arrival time of the target ship, or a shore crane apparatus that is about to complete its operation task at the arrival time of the target ship.

As an optional implementation of the embodiment of the present disclosure, when determining the target shore crane apparatus based on the ship arrival time and the operation time information of each shore crane apparatus in the shore crane apparatus information, if the operation area of the target ship is enough for two or more shore crane apparatuses to perform hoisting operations, the scheduling center system 1 can select two or more of the shore crane apparatuses in the idle state based on size information and the operation area of the ship, as target shore crane apparatuses. In the ship unloading operation, different target shore crane apparatuses can hoist containers within their respective operation ranges in accordance with the ship unloading task and load the containers onto transportation vehicles, so as to shorten the operation time and improve the operation efficiency.

As an optional implementation of the embodiment of the present disclosure, during the ship unloading process, if the currently determined target shore crane apparatus cannot meet a container hoisting requirement, e.g., when the currently determined target shore crane apparatus malfunctions during the hoisting operation, the scheduling center system 1 can reselect another available hoisting apparatus as a new target shore crane apparatus based on current time information and the operation time information of each shore crane apparatus in the shore crane apparatus information.

As an optional implementation of the embodiment of the present disclosure, the scheduling center system 1 can determine the target container area for each container based on the type of goods carried by the container and the information on container areas in the port area as follows. The warehouse center in the port area can be divided into different container areas depending on the types of goods they can store. The scheduling center system 1 can obtain the type of goods carried by the container; and determine the target container area in the warehouse center for storing the type of goods to store the container unloaded from the ship, based on information on the types of goods each container area in the warehouse center of the port area can store.

In some optional embodiments, the scheduling center system 1 generating the ship berthing task and the ship unloading task based on the ship unloading plan may include: generating the ship berthing task containing identification information and an operation area of the target shore crane apparatus, based on the ship unloading plan; and generating the ship unloading task containing identification information of the target ship, ship unloading start time, ship unloading end time and identification information and a target container area for each container, based on the ship unloading plan.

In some optional embodiments, the ship unloading task may include a ship unloading task list recording the identification information of the target ship, the identification information of the target shore crane apparatus, the identification information of each container to be unloaded at the port and its corresponding target container area.

In some optional embodiments, the scheduling center system 1 can be further configured to generate the container storage task based on the ship unloading plan and transmit the container storage task to the warehouse management system 5 of a warehouse center.

In some optional embodiments, the container storage task can include a container storage task list recording identification information of the warehouse management system, the identification information of each container to be stored in the warehouse center and its corresponding target container area.

In some optional embodiments, the scheduling center system 1 can be further configured to generate the container loading task based on the ship unloading plan and transmit the container loading task to the vehicle control system 4 of the transportation vehicle.

In some optional embodiments, the scheduling center system 1 can be further configured to determine, after the shore crane apparatus has loaded the container onto the transportation vehicle, the container unloading location based on the target container area for the container, generate the container unloading task containing the container unloading location and transmit the container unloading task to the vehicle control system 4 of the transportation vehicle.

In some embodiments, in the port area, a container loading location and a container unloading location, which may be one and the same location or two different locations, can be predetermined for each container area. The container loading and unloading locations corresponding to each container area in the port area can be stored in advance in the scheduling center system 1 and/or the shore crane control system 3.

In some optional embodiments, the ship control system 2 transmitting the ship information and the container information to the scheduling center system 1 may include: determining a travel time length from a current location of the target ship to the port based on the current location, a location of the port and a travel route; estimating arrival time at which the target ship arrives at the port based on the travel time length and current time; and transmitting the ship information containing the estimated arrival time and ship state information and the container information to the scheduling center system 1.

In an optional embodiment, the arrival time at which the target ship arrives at the port can be estimated based on a departure location, the location of the target port and the predetermined travel route when the target ship is to travel from the departure location to the target port. As an example, the ship control system 2 of the target ship can determine the predetermined travel route based on the departure location and the location of the port, estimate a travel speed of the ship based on a current weather condition and maritime information obtained at the time of departure, calculate the required travel time length of the ship and obtain the estimated arrival time based on the current time.

In an optional embodiment, the arrival time at which the target ship arrives at the port can be obtained as follows. While the target ship is traveling, the ship control system 2 can determine the location of the ship, calculate the required travel time length of the ship based on the location of the ship, the location of the port, the travel route and a current travel speed of the ship, and obtain the estimated arrival time based on the current time.

In an optional embodiment, while the target ship is traveling, it may encounter various different travel conditions, e.g., the weather or maritime conditions may vary or the ship may need to wait or yield to other ships, such that the ship may not be able to travel according to the travel route and speed predetermined at the time of departure. In this case, the ship control system 2 can determine the location of the target ship, re-plan the route based on the location of the target ship, determine the travel speed, calculate the required travel time length of the ship, obtain the estimated arrival time based on the current time, and transmit the newly estimated arrival time to the scheduling center system 1.

In an optional embodiment, when the target ship approaches the area where the target shore crane apparatus is located, the ship control system 2 can control the target ship to move to the operation area of the target shore crane apparatus in accordance with the received ship berthing task containing the identification information and operation area of the target shore crane apparatus. When the target ship is in position, the ship control system 2 can transmit the ship in-position notification message to the shore crane control system 3 of the target shore crane apparatus and wait for the ship unloading operation.

In an optional embodiment, after entering a wireless signal coverage of the port, the ship control system 2 of the target ship can establish communication with the target shore crane apparatus wirelessly based on the identification information of the target shore crane apparatus, determine the location of the target shore crane apparatus based on the identification information of the target shore crane apparatus, plan a route for moving to the operation area of the target shore crane apparatus, adjust the planed travel route by communicating with the shore crane apparatus, arrive at the operation area and prepare for container unloading.

In an embodiment of the present disclosure, the target ship can plan the travel route from the location of the target ship to the port or from the current location to the operation area by using any existing navigation algorithm or by using any third-party navigation software (the present disclosure is not limited thereto).

In an embodiment of the present disclosure, the ship state information may include information on the remaining fuel, information on the current location, information on the tonnage of the ship, information on the draught of the ship, and the like. In generating the ship unloading plan, the scheduling center system 1 can schedule a ship having a low level of remaining fuel to berth first based on the information on the remaining fuel of the ship, select a shore crane apparatus having an appropriate distance from the shore crane apparatuses in the idle state based on the information on the current location, select a shore crane apparatus suitable for the target ship to berth from the shore crane apparatuses in the idle state based on the information on the tonnage and draught of the ship, and finally select one shore crane apparatus as the target shore crane apparatus.

In some optional embodiments, the shore crane control system 3 controlling the target shore crane apparatus to load the container on the target ship onto the transportation vehicle in accordance with the ship unloading task may include: the shore crane control system 3 confirming an identity of the container on the target ship and controlling the target shore crane apparatus to hoist the container when the identity is confirmed; and controlling the target shore crane apparatus to load the container onto the transportation vehicle upon receiving a vehicle in-position notification message from the vehicle control system 4 of the transportation vehicle.

In an optional embodiment, the shore crane control system 3 can confirm the identities of the containers on the target ship in a predetermined container unloading order and control the target shore crane apparatus to hoist each container when its identity is confirmed. Upon receiving the vehicle in-position notification message from the vehicle control system 4 of the transportation vehicle, the shore crane control system 3 can control the target shore crane apparatus to load the container onto the transportation vehicle, mark the container as in an unloaded state in the ship unloading task, and transmit a ship unloading completion notification message to the scheduling center system 1 and/or the ship control system 2 of the target ship when it is determined that all containers in the ship unloading task are in the unloaded state.

As an example, the containers on the target ship can be arranged in columns, with multiple containers being stacked in layers in each column. The predetermined container unloading order can be obtained as follows. The shore crane control system 3 can determine the location of each container to be unloaded on the ship based on the ship information and container information in the ship unloading task, and generate a container unloading order in which the containers are unloaded by columns, from top to bottom per column, based on the number of containers to be unloaded and the identification information of each of the containers.

In some optional embodiments, the shore crane control system 3 can be further configured to, when the confirmation of the identity fails, lift and place the container on top of another column of containers whose identities have been confirmed on the target ship.

In an embodiment, when the shore crane control system 3 is controlling the shore crane apparatus to unload the containers on the ship, the containers on the target ship can be unloaded by columns, layer by layer from top to bottom per column (the containers are unloaded one column after another). When the hoisting process begins, the shore crane control system 3 can confirm an identity of a container on the ship based on the identification information of the container in the ship unloading task, control the target shore crane apparatus to lift the container when the identity is confirmed, and upon receiving the vehicle in-position notification message from the vehicle control system 4 of the transportation vehicle, control the target shore crane apparatus to load the container onto the transportation vehicle and mark the container as in the unloaded state in the ship unloading task.

In an embodiment of the present disclosure, different contains carried by the target ship may have different destination ports and only some of the containers need to be unloaded at the target port. Thus, when unloading the container, it is required to re-arrange the container not to be unloaded at the target port on the target ship. In order to reduce the workload of the shore crane apparatus, the shore crane control system 3 can confirm an identity of a container on the ship based on the identification information of the container in the ship unloading task, and when the confirmation of the identity fails, control the target shore crane apparatus to lift and place the container on top of another column of containers whose identities have been confirmed on the target ship.

In an embodiment of the present disclosure, due to the limited operation area of the shore crane apparatus, in order to improve the operation efficiency, the shore crane control system 3 can control the target shore crane apparatus to lift the container first, and while the container is in a lifted state, upon receiving the vehicle in-position notification message from the vehicle control system 4 of the transportation vehicle, load the container onto the transportation vehicle. After the container is loaded, the transportation vehicle leaves the container loading location immediately. The shore crane control system 3 can control the target shore crane apparatus to lift the next container to be loaded and wait for the vehicle in-position notification for the next transportation vehicle. Each time a loading operation for a container has completed, the container is marked as in the unloaded state in the ship unloading task, until the ship unloading task is completed. When confirming that all containers in the ship unloading task are in the unloaded state, the shore crane control system 3 can transmit a ship unloading completion notification message to the scheduling center system 1 and/or the ship control system 2 of the target ship.

In some optional embodiments, the identification information of the container can be provided at the surface of the container. For example, the tag can be a Quick Response (QR) code or a barcode, and the shore crane control system 3 can confirm the identity of the container on the target ship by recognizing the QR code or barcode on the container.

In an optional embodiment, the shore crane control system 3 can include an identity recognition device, which can be a camera, a code reader or any other device capable of recognizing a QR code or barcode (the present disclosure is not limited thereto). As an exemplary implementation of the embodiment of the present disclosure, the identity recognition device can be provided on a hoisting arm of the target shore crane apparatus and can obtain the identification information of the container by scanning the QR code or barcode on the container, compare the identification information of the container with the identification information of the container in the ship unloading task, and determine that the identity is confirmed when they match each other, or otherwise determine that the confirmation of the identity fails.

In an optional embodiment, the tag can be an electronic tag bound to the identification information of the container. Accordingly, the identity recognition device can be an inductive reader for obtaining the identification information of the container by reading the identification information of the container from the electronic tag, comparing the identification information of the container with the identification information of the container in the ship unloading task, and determining that the identity is confirmed when they match each other, or otherwise determining that the confirmation of the identity fails.

In an optional embodiment, the shore crane control system 3 can obtain its own location information by means of positioning, and exchange information with the ship control system 2 and the vehicle control system 4, so as to obtain the location information of the target ship and the location information of the transportation vehicle, and hoist the container onto the transportation vehicle based on its own location information, the location information of the target ship and the location information of the transportation vehicle.

In an optional embodiment, the hoisting arm of the shore crane apparatus can be provided with an end effector, and the container can be provided with a grab section coordinated with the end effector. The shore crane apparatus lifts the container by grabbing the grab section of the container with the end effector.

In an optional embodiment, in a container lifting operation, the shore crane control system 3 can capture an image of the grab section of the container, determine orientation information of the grab section based on the image, and adjust a movement gesture of the end effector based on the orientation information of the grab section, such that the end effector can grab the grab section precisely to lift the container.

In an embodiment of the present disclosure, the hoisting arm can be a hoister. A lock can be provided at each of four corners of a lower part of the hoister (i.e., the four locks constitute the end effector). A lock hole coordinated with the lock is provided at each of four corners of the top of the container (i.e., the four lock holes constitute the grab section). When the four locks of the hoister are inserted into the four lock holes on the containers, the hoister can lift the container. Of course, in some other examples, the hoisting arm can be a hoister having a hook provided at its lower part (i.e., the hook constitutes the end effector). A buckle or ring can be provided on the top of the container. When the hook of the hoister is hooked to the buckle or ring on the top of the container, the hoister can lift the container.

In some optional embodiments, the shore crane control system 3 can be further configured to establish association information between the transportation vehicle and the container after controlling the target shore crane apparatus to load the container onto the transportation vehicle, and transmit the association information to the scheduling center system 1.

In an embodiment of the present disclosure, in order to guarantee the correspondence between the transportation vehicle and the container it carries, the shore crane control system 3 can associate the transportation vehicle and the container based on identification information of the transportation vehicle and the identification information of the container when loading the container onto the transportation vehicle.

As an optional implementation of the embodiment of the present disclosure, in the above embodiment, the scheduling center system 1 generating the container unloading task containing the container unloading location based on the target container area for the container may include: the scheduling center system 1 determining, upon receiving the association information between the transportation vehicle and the container from the shore crane control system 3, the container unloading location for the container based on the target container area for the container in the association information and generating the container unloading task containing the container unloading location.

In some optional embodiments, the warehouse management system 5 assigning the warehouse hoisting apparatus to hoist each target container carried by the transportation vehicle to the corresponding storage location in accordance with the container storage task may include: the warehouse management system 5 confirming, upon receiving a container unloading in-position notification message from the vehicle control system 4 of the transportation vehicle, an identity of the container in the container unloading in-position notification message, and transmitting a container unloading hoisting task containing the storage location of the container to a hoisting control system of the warehouse hoisting apparatus when the identity is confirmed; the hoisting control system of the warehouse hoisting apparatus lifting the container on the transportation vehicle and placing it at the storage location associated with the container unloading hoisting task upon receiving the container unloading hoisting task, and transmitting a container unloading completion notification message to the warehouse management system 5 and/or the vehicle control system 4 of the transportation vehicle; and the warehouse management system 5 marking the container as in a stored state in the container storage task upon receiving the container unloading completion notification message, and transmitting a container storage task completion notification message to the scheduling center system 1 or the shore crane control system 3 when it is determined that all containers in the container storage task have been marked as in the stored state.

In some optional embodiments, the vehicle control system 4 can be further configured to transmit a container loading in-position notification message to the shore crane control system 3 of the shore crane apparatus corresponding to the container loading location when controlling the transportation vehicle to move to the container loading location, and transmit a container unloading in-position notification message to the warehouse management system 5 corresponding to the container unloading location when controlling the transportation vehicle to move to the container unloading location.

In an embodiment of the present disclosure, the vehicle control system 4 can be configured to determine a current location of the transportation vehicle, plan a travel route from the current location of the transportation vehicle to the container loading location or container unloading location based on the container loading task or container unloading task for the transportation vehicle, obtain environment information and determine a sensed result, determine travel decision information based on the sensed result and the travel route, and control the transportation vehicle to move to the container loading location or container unloading location along the travel route based on the travel decision information.

In an embodiment of the present disclosure, the sensed result may include information on e.g., a type, shape, contour, location and distance of an obstacle around the mobile hoisting apparatus. The vehicle control system 4 can obtain the above sensed result by recognizing the environment information using any existing visual processing techniques such as object detection, object tracking and semantic segmentation (the present disclosure is not limited thereto). The vehicle control system 4 can plan the travel route from the current location of the transportation vehicle to the container loading location or container unloading location using its own navigation algorithm or any third-party navigation software (the present disclosure is not limited thereto). The travel decision information may include steering information (including information on steering angle), acceleration information (including information on an opening degree of a throttle pedal), deceleration information (including information on an opening degree of a brake pedal), gear information (including information on driving, reverse or neutral gear), and the like. The specific decision algorithm can be similar to the existing decision algorithm used in the self-driving vehicles and details thereof will be omitted here.

In some optional embodiments, when transmitting the container storage task to the warehouse management system of the warehouse center, the scheduling center system 1 can determine, based on operation time information of each warehouse hoisting apparatus in the warehouse hoisting apparatus information in the port area, at least one warehouse hoisting apparatus that is in the idle state at predetermined hoisting time, and select one or more warehouse hoisting apparatuses from the determined at least one warehouse hoisting apparatus for assigning to the warehouse center. The predetermined hoisting time can be the ship unloading start time or the time at which the transportation vehicle is estimated to arrive at the warehouse center. Of course, in some optional embodiments, the warehouse center of the port has a pre-assigned corresponding warehouse hoisting apparatus and there is no need for the scheduling center system 1 to assign the warehouse hoisting apparatus.

In an embodiment of the present disclosure, the storage area of the warehouse center can be divided into a number of container areas depending on the types of container goods they can store. The containers in each container area are stacked in layers per column. The container storage task transmitted from the scheduling center system 1 to the warehouse management system 5 of the warehouse center may contain the identification information of the container and the target container area for the container. Upon receiving the container unloading in-position notification message from the vehicle control system 4 of the transportation vehicle, the warehouse management system 5 can compare the identification information of the container in the container unloading in-position notification message with the identification information of the container in the container storage task, and determine that the identity is confirmed when they match each other. In this case, the warehouse management system 5 can confirm the storage location of the container from available storage locations in the target container area based on the target container area for the container in the container storage task, generate the container unloading hoisting task containing the storage location of the container, and transmit the container unloading hoisting task to the hoisting control system of the warehouse hoisting apparatus. If they do not match, no further operation is performed and a warning message of leaving or wrong container area can be transmitted to the vehicle control system 4 of the transportation vehicle.

In an optional embodiment, the hoisting control system can determine its own location information by means of positioning, communicate with the warehouse management system 5 and the vehicle control system 4 to obtain the storage location information of the container and the location information of the transportation vehicle, and hoist the container on the transportation vehicle to the storage location of the container based on its own location information, the storage location information of the container and the location information of the transportation vehicle.

In an optional embodiment, the warehouse hoisting apparatus can be a rubber-tired gantry crane, a rail-mounted gantry crane or a forklift. The warehouse hoisting apparatus is provided with a hoisting arm, which can be a mechanical arm or a hoister (the present disclosure is not limited thereto). In an exemplary embodiment, the hoisting arm of the warehouse hoisting apparatus may have a specific structure similar to the hoisting arm of the shore crane apparatus. For the lifting operation process for the warehouse hoisting apparatus to lift the container, reference can be made to the lifting operation process for the shore crane apparatus and details thereof will be omitted here.

In some optional embodiments, the container storage task in the above embodiment can be generated by the shore crane control system 3 based on the ship unloading task and transmitted to the warehouse management system 5 of the warehouse center.

In some optional embodiments, the container loading task in the above embodiment can be generated by the shore crane control system 3 based on the ship unloading task and transmitted to the vehicle control system 4 of the transportation vehicle.

In some optional embodiments, the shore crane control system 3 can generate the container unloading task containing the container unloading location based on the target container area for the container after controlling the target shore crane apparatus to load the container onto the transportation vehicle, and transmit the container unloading task to the vehicle control system 4 of the transportation vehicle.

In an embodiment of the present disclosure, a warehouse management system 5 can manage one or more container areas. If the target container areas for the containers in the ship unloading plan are distributed across a plurality of warehouse management systems, the scheduling center system 1 (or the shore crane control system 3) can generate a plurality of container storage tasks and transmit them to the respective warehouse management systems 5. Assuming that one warehouse management system 5 manages one container area and the target container areas for a number, N, of containers in a ship unloading plane (ship unloading task) are distributed over Container Area A, Container Area B, Container Area C and Container Area D managed by Warehouse Management Systems A-D, respectively, the scheduling center system 1 (or the shore crane control system 3) can generate four container storage tasks, with the containers in each container storage task having the same target container area, and transmit the four container storage tasks to Warehouse Management Systems A-D, respectively.

In an optional embodiment, the remote communication between the scheduling center system 1 and the ship control system 2 of the target ship can be performed by means of satellite communication. For the implementation of the satellite communication between the ship control system 2 and the scheduling center system 1, reference can be made to the existing satellite communication technology and details thereof will be omitted here. Within the wireless signal coverage of the port, the scheduling center system 1, the shore crane control system 3 of the target shore crane apparatus, the warehouse management systems 5 of the warehouse center and the vehicle control system 4 of the transportation vehicle can communicate with each other by means of wireless communication. The wireless communication can be Narrow Band Internet of Things (NB-IoT), 4G, WIFI, Zigbee or the like, and the present disclosure is not limited thereto.

With the intelligent port control system according to the embodiments of the present disclosure, for an operation of unloading a container from a ship at a port, a scheduling center system, a ship control system, a shore crane control system, a warehouse management system and a vehicle control system exchange information with each other, so as to achieve fully automated, unmanned loading/unloading operations at the port, thereby improving the intelligence level of the loading/unloading and transportation operations of containers at the port, reducing requirements on human resources and labor cost, improving operation efficiency and avoiding the problem associated with lack of safety guarantee for operators.

Based on the same concept, according to an embodiment of the present disclosure, a scheduling center system 1 is provided. Referring to FIG. 2 , the scheduling center system 1 includes at least one machine executable instruction. The at least one machine executable instruction includes a scheduling communication module 101, a plan generation module 102 and a task generation module 103. The at least one machine executable instruction is executed by a processor such that: the scheduling communication module 101 is configured to transmit and receive information, the plan generation module 102 is configured to generate a ship unloading plan based on ship information and container information of a target ship and shore crane apparatus information as received by the scheduling communication module 101, and the task generation module 103 is configured to generate a ship berthing task and a ship unloading task based on the ship unloading plan, and transmit the ship berthing task and the ship unloading task to a ship control system of the target ship and a shore crane control system of a target shore crane apparatus, respectively, via the scheduling communication module 101 (the scheduling communication module 101 transmits the ship berthing task to the ship control system of the target ship and transmits the ship unloading task to the shore crane control system of the target shore crane apparatus).

In some optional embodiments, the scheduling communication module 101 can transmit and receive information using any of various communication protocols. The transmitted or received information can be transmitted or received via an antenna or transceiver coupled to the communication module 101.

In some optional embodiments, the task generation module 103 can be further configured to generate a container storage task based on the ship unloading plan and transmit the container storage task to a warehouse management system 5 of a warehouse center via the scheduling communication module 101.

In some optional embodiments, the task generation module 103 can be further configured to generate a container loading task based on the ship unloading plan and transmit the container loading task to a vehicle control system of a corresponding transportation vehicle via the scheduling communication module 101, and, upon receiving association information between the transportation vehicle and a container via the scheduling communication module 101, generate a container unloading task containing a container unloading location based on a target container area for the container and transmit the container unloading task to the vehicle control system of the transportation vehicle in the association information via the scheduling communication module 101.

Based on the same application concept, according to an embodiment of the present disclosure, a scheduling center system 1 is provided. The scheduling center system 1 includes at least one processor and at least one memory. The at least one memory stores at least one machine executable instruction executable by the at least one processor. The at least one machine executable instruction includes the modules shown in FIG. 2 . The at least one machine executable instruction can also provide modules for functions such as an operating system and a human-machine interaction interface. The at least one processor executes the at least one machine executable instruction to implement the above described operations, processes and functions of the scheduling center system 1 as shown in FIG. 1 . The scheduling center system 1 according to the embodiment of the present disclosure can be provided at a specified location in a port, e.g., at a central control center or a centralized control center. The control center can further include other control systems or scheduling systems and can communicate with other external management systems, e.g., a customs management system. The scheduling center system 1 according to the embodiment of the present disclosure can also communicate with the other systems in the control center and/or the external management systems.

Based on the same application concept, according to an embodiment of the present disclosure, a ship control system 2 is provided. Referring to FIG. 3 , the ship control system 2 includes at least one machine executable instruction. The at least one machine executable instruction includes a ship communication module 201 and a ship control module 202. The at least one machine executable instruction is executed by a processor such that: the ship communication module 201 is configured to transmit and receive information, and the ship control module 202 is configured to transmit ship information and container information to a scheduling center system via the ship communication module 201, and upon receiving a ship berthing task from the scheduling center system via the ship communication module 201, control a target ship to move to an operation area corresponding to a target shore crane apparatus, and transmit a ship in-position notification message to a shore crane control system of the target shore crane apparatus via the ship communication module 201.

In some optional embodiments, the ship communication module 201 can transmit and receive information using any of various communication protocols. The transmitted or received information can be transmitted or received via an antenna or transceiver coupled to the communication module 201.

Based on the same application concept, according to an embodiment of the present disclosure, a ship control system 2 is provided. The ship control system 2 includes at least one processor and at least one memory. The at least one memory stores at least one machine executable instruction executable by the at least one processor. The at least one machine executable instruction includes the modules shown in FIG. 3 . The at least one machine executable instruction can also provide modules for functions such as an operating system and a human-machine interaction interface. The at least one processor executes the at least one machine executable instruction to implement the above described operations, processes and functions of the ship control system 2 as shown in FIG. 1 .

Based on the same application concept, according to an embodiment of the present disclosure, a ship is provided. The ship includes the ship control system 2 according to the above embodiment. The description of the structure of the ship control system 2 will be omitted here. The ship control system 2 can communicate with other control devices or control apparatuses in the ship, such that these systems, control devices or apparatuses cooperate to achieve navigation and control of the ship, thereby allowing the ship to travel efficiently.

Based on the same application concept, according to an embodiment of the present disclosure, a shore crane control system 3 is provided. Referring to FIG. 4 , the shore crane control system 3 includes at least one machine executable instruction. The at least one machine executable instruction includes a shore crane communication module 301 and a hoisting control module 302. The at least one machine executable instruction is executed by a processor such that: the shore crane communication module 301 is configured to transmit and receive information, and the hoisting control module 302 is configured to receive a ship unloading task from a scheduling center system 1 via the shore crane communication module 301, and upon receiving a ship in-position notification message from a ship control system via the shore crane communication module 301, control a target shore crane apparatus to load a container on a target ship onto a transportation vehicle in accordance with the ship unloading task.

In some optional embodiments, the shore crane communication module 301 can transmit and receive information using any of various communication protocols. The transmitted or received information can be transmitted or received via an antenna or transceiver coupled to the communication module 301.

In some optional embodiments, referring to FIG. 5 , the shore crane control system 3 can further include a shore crane task generation module 303 configured to generate a container storage task based on the ship unloading task and transmit the container storage task to a warehouse management system 5 of a warehouse center via the shore crane communication module 301.

In some optional embodiments, the hoisting control module 302 controlling the target shore crane apparatus to load the container on the target ship onto the transportation vehicle in accordance with the ship unloading task may include: confirming an identity of the container on the target ship and controlling the target shore crane apparatus to hoist the container when the identity is confirmed; and controlling the target shore crane apparatus to load the container onto the transportation vehicle upon receiving a vehicle in-position notification message from a vehicle control system of the transportation vehicle via the shore crane communication module 301.

In some optional embodiments, the hoisting control module 302 can be further configured to establish association information between the transportation vehicle and the container after controlling the target shore crane apparatus to load the container onto the transportation vehicle.

In some optional embodiments, the hoisting control module 302 can be further configured to transmit the association information to the scheduling center system 1 via the shore crane communication module 301.

In some optional embodiments, the shore crane task generation module 303 can be further configured to generate a container loading task based on the ship unloading task and transmit the container loading task to a vehicle control system 4 of the transportation vehicle via the shore crane communication module 301, and after controlling the target shore crane apparatus to load the container onto the transportation vehicle, generate a container unloading task containing a container unloading location based on a target container area for the container and transmit the container unloading task to the vehicle control system 4 of the transportation vehicle via the shore crane communication module 301.

Based on the same application concept, according to an embodiment of the present disclosure, a shore crane control system 3 is provided. The shore crane control system 3 includes at least one processor and at least one memory. The at least one memory stores at least one machine executable instruction executable by the at least one processor. The at least one machine executable instruction includes the modules shown in FIG. 4 or 5 . The at least one machine executable instruction can also provide modules for functions such as an operating system and a human-machine interaction interface. The at least one processor executes the at least one machine executable instruction to implement the above described operations, processes and functions of the shore crane control system 3 as shown in FIG. 1 .

Based on the same application concept, according to an embodiment of the present disclosure, a shore crane apparatus is provided. The shore crane apparatus includes the shore crane control system 3 according to the above embodiment. The shore crane control system 3 can be provided in a control room of the shore crane apparatus. The control room may further include other systems, apparatuses and devices for controlling the shore crane apparatus. Alternatively, the shore crane control system 3 can be provided at any other specified location on the shore crane apparatus. The shore crane control system 3 can communicate with the other systems, apparatuses and devices in the control room, such that these systems, apparatuses and devices cooperate to control the operations of the shore crane apparatus.

Based on the same application concept, according to an embodiment of the present disclosure, a vehicle control system 4 is provided. Referring to FIG. 6 , the vehicle control system 4 includes at least one machine executable instruction. The at least one machine executable instruction includes a vehicle communication module 401 and a vehicle control module 402. The at least one machine executable instruction is executed by a processor such that: the vehicle communication module 401 is configured to transmit and receive information, and the vehicle control module 402 is configured to control, upon receiving a container loading task via the vehicle communication module 401, a transportation vehicle to move to a container loading location associated with the container loading task for loading a container in accordance with the container loading task, and to control, upon receiving a container unloading task via the vehicle communication module 401, the transportation vehicle to move to a container unloading location associated with the container unloading task for unloading a container in accordance with the container unloading task.

In some optional embodiments, the vehicle communication module 401 can transmit and receive information using any of various communication protocols. The transmitted or received information can be transmitted or received via an antenna or transceiver coupled to the communication module 401.

Based on the same application concept, according to an embodiment of the present disclosure, a vehicle control system 4 is provided. The vehicle control system 4 includes at least one processor and at least one memory. The at least one memory stores at least one machine executable instruction executable by the at least one processor. The at least one machine executable instruction includes the modules shown in FIG. 6 . The at least one machine executable instruction can also provide modules for functions such as an operating system and a human-machine interaction interface. The at least one processor executes the at least one machine executable instruction to implement the above described operations, processes and functions of the vehicle control system 4 as shown in FIG. 1 .

Based on the same application concept, according to an embodiment of the present disclosure, a transportation vehicle is provided. The transportation vehicle includes the vehicle control system 4 according to the above embodiment. The transportation vehicle may further include other sensor systems, vehicle networking systems and control systems. The vehicle control system 4 can communicate with these systems so as to enable efficient navigation and safe travel of the vehicle.

Based on the same application concept, according to an embodiment of the present disclosure, a warehouse management system 5 is provided. Referring to FIG. 7 , the warehouse management system 5 includes at least one machine executable instruction. The at least one machine executable instruction includes a warehouse communication module 501 and a warehouse management module 502. The at least one machine executable instruction is executed by a processor such that: the warehouse communication module 501 is configured to transmit and receive information, and the warehouse management module 502 is configured to assign, upon receiving a container storage task via the warehouse communication module 501, a warehouse hoisting apparatus to hoist each target container carried by a transportation vehicle to a corresponding storage location in accordance with the container storage task.

In some optional embodiments, the vehicle communication module 501 can transmit and receive information using any of various communication protocols. The transmitted or received information can be transmitted or received via an antenna or transceiver coupled to the communication module 501.

In some optional embodiments, the warehouse management module 502 assigning the warehouse hoisting apparatus to hoist each target container carried by the transportation vehicle to the corresponding storage location in accordance with the container storage task may include: the warehouse management module 502 confirming, upon receiving a container unloading in-position notification message from a vehicle control system of the transportation vehicle via the warehouse communication module 501, an identity of the container in the container unloading in-position notification message, and transmitting a container unloading hoisting task containing a storage location of the container to a hoisting control system of the warehouse hoisting apparatus via the warehouse communication module 501 when the identity is confirmed; and the warehouse management module 502 marking the container as in a stored state in the container storage task upon receiving a container unloading completion notification message associated with the container from the hoisting control system of the warehouse hoisting apparatus via the warehouse communication module 501, and transmitting a container storage task completion notification message to a scheduling center system 1 or a shore crane control system 3 via the warehouse communication module 501 when it is determined that all containers in the container storage task have been marked as in the stored state.

Based on the same application concept, according to an embodiment of the present disclosure, a warehouse management system 5 is provided. The warehouse management system includes at least one processor and at least one memory. The at least one memory stores at least one machine executable instruction executable by the at least one processor. The at least one machine executable instruction includes the modules shown in FIG. 7 . The at least one machine executable instruction can also provide modules for functions such as an operating system and a human-machine interaction interface. The at least one processor executes the at least one machine executable instruction to implement the above described operations, processes and functions of the warehouse management system 5 as shown in FIG. 1 .

Unless stated otherwise specifically, terms such as processing, calculating, operating, determining, displaying and the like may refer to an action and/or procedure performed by one or more processing or computing systems or similar devices. The action and/or procedure can be represented as a data operation on a physical (e.g., electronic) quantity in a register or memory of a processing system or a conversion into other data similarly represented as a physical quantity in a memory or register of a processing system or any other similar information storage, transmission or display device. Information or signals can be represented using any of various different techniques and methods. For example, the data, instructions, commands, information, signals, bits, symbols and chips mentioned throughout the above description can be represented using voltages, currents, electromagnetic waves, magnetic fields or particles, optical fields or particles, or any combination thereof.

It should be noted that any particular order or hierarchy of the steps in the disclosed process is only an example of an exemplary method. It can be appreciated that, depending on design preferences, the particular order or hierarchy of the steps in the disclosed process can be re-arranged without departing from the scope of the present disclosure. The method claims as attached show elements of the respective steps in an exemplary order, but they are not limited to the particular order or hierarchy as described.

In the above detailed description, various features may be combined together in one single embodiment for simplicity. However, such disclosure should not be interpreted as reflecting an intent that the implementation of the claimed subject matter requires more features than those clearly defined in each claim. Rather, as reflected by the claims as attached, the present disclosure may be in a state having less than all features of the one single embodiment as disclosed. Therefore, the claims are hereby explicitly incorporated into the detailed description and each claim individually constitutes a separate preferred embodiment of the present disclosure.

It can be appreciated by those skilled in the art that various illustrative logic blocks, modules, circuits and algorithm steps described in connection with the embodiments of the present disclosure can be implemented as electronic hardware, computer software or any combination thereof. In order to clearly illustrate the interchangeability between the hardware and the software, the illustrative components, blocks, modules, circuits and steps have been described above generally with respect to their functions. Depending on specific applications and design constraints applied to the entire system, the functions can be implemented in either hardware or software. For each specific application, those skilled in the art can implement the described function flexibly. However, such implementation decision should not be interpreted as departing from the scope of the present disclosure.

The steps of the methods or algorithms described in connection with the embodiments of the present disclosure can be embodied directly as hardware, software modules executable by processors or any combination thereof. The software modules can be provided in a RAM, a flash memory, a ROM, an EPROM, an EEPROM, a register, a hard drive, a removable magnetic drive, a CD-ROM or any other form of storage medium known in the art. An exemplary storage medium is connected to a processor, such that the processor can read information from the storage medium or write information into the storage medium. Of course, the storage medium can alternatively be a component of the processor. The processor and the storage medium can be provided in an ASIC. The ASIC can be in a user terminal. Of course, the processor and the storage medium can be provided as separate components in a user terminal.

For software implementations, the technique described in the present disclosure can be implemented using modules (e.g., processes, functions or the like) performing the functions described in the present disclosure. These software codes can be stored in a memory unit and executed by a processor. The memory unit can be provided within the processor or externally to the processor. In the latter case, it can be communicatively coupled to the processor in various ways known in the art.

The above description includes examples of one or more embodiments. Of course, it would be impossible to describe all possible combinations of components or methods in order to describe the above embodiments. However, it can be appreciated by those skilled in the art that the embodiments can be further combined and arranged. Thus, the embodiments described herein are intended to cover all such changes, modifications and variants that fall within the scope of the claims as attached. Further, the term “including” as used in the description or claims has a coverage similar to that of the term “comprising” when used in the claims as a transition word. Moreover, any term “or” as used in the claims or description is to be interpreted as “or in a non-exclusive sense”. 

What is claimed is:
 1. A ship control system, comprising: one or more processors; and a memory that stores at least one machine executable instruction that when executed by the one or more processors causes the one or more processors to perform a method, comprising: transmit ship information and container information to a scheduling center system; and upon receiving a ship berthing task from the scheduling center system, control a target ship to move to an operation area corresponding to a target shore crane apparatus, and transmit a ship in-position notification message to a shore crane control system of the target shore crane apparatus.
 2. The ship control system of claim 1, wherein the one or more processors are further configured to: determine a travel time length from a current location of the target ship to a port based on the current location of the target ship, a location of the port and a travel route; estimate an arrival time at which the target ship arrives at the port based on the travel time length; and transmit the ship information containing the estimated arrival time and ship state information and the container information to the scheduling center system.
 3. The ship control system of claim 1, wherein the ship information comprises at least one of ship arrival time or ship state information.
 4. The ship control system of claim 3, wherein the one or more processors are further configured to: estimate the ship arrival time based on a departure location, a location of a port and a travel route.
 5. The ship control system of claim 3, wherein the one or more processors are further configured to: determine a travel route based on a departure location and a location of a port; estimate a travel time length of the target ship based on the travel route, a current weather condition and maritime information obtained at time of departure of the target ship; and estimate the ship arrival time based on the estimated travel time length.
 6. The ship control system of claim 3, wherein the one or more processors are further configured to: determine a current location of the target ship, calculate a travel time length of the target ship based on the current location of the target ship, a location of a port, a travel route and a current travel speed of the target ship, while the target ship is traveling; and estimate the ship arrival time based on the travel time length.
 7. The ship control system of claim 3, wherein the ship state information comprises at least one of information on remaining fuel of the target ship, information on a current location of the target ship, information on tonnage of the target ship, or information on draught of the target ship.
 8. The ship control system of claim 1, wherein the container information comprises at least one of a number of containers, identification information or a type of goods carried by each container.
 9. The ship control system of claim 1, wherein the one or more processors are further configured to: in response to entering a wireless signal coverage of a port, establish communication with the target shore crane apparatus wirelessly based on identification information of the target shore crane apparatus; and determine a location of the target shore crane apparatus based on the identification information of the target shore crane apparatus; plan a route for moving to the operation area of the target shore crane apparatus based on the location of the target shore crane apparatus.
 10. The ship control system of claim 1, wherein the received ship berthing task comprises identification information and the operation area of the target shore crane apparatus.
 11. The ship control system of claim 10, wherein the one or more processors are further configured to: control the target ship to move to the operation area of the target shore crane apparatus in accordance with the identification information and the operation area of the target shore crane apparatus.
 12. A vehicle control system, comprising: one or more processors; a memory storing at least one machine executable instruction, wherein the at least one machine executable instruction when executed by the one or more processors causes the one or more processors to perform a method, comprising: control, upon receiving a container loading task, a transportation vehicle to move to a container loading location associated with the container loading task for loading a container in accordance with the container loading task; and control, upon receiving a container unloading task, the transportation vehicle to move to a container unloading location associated with the container unloading task for unloading a container in accordance with the container unloading task.
 13. The vehicle control system of claim 12, wherein the one or more processors are further configured to: transmit a container loading in-position notification message to a shore crane control system of a shore crane apparatus corresponding to the container loading location when controlling the transportation vehicle to move to the container loading location.
 14. The vehicle control system of claim 12, wherein the one or more processors are further configured to: transmit a container unloading in-position notification message to a warehouse management system corresponding to the container unloading location when controlling the transportation vehicle to move to the container unloading location.
 15. The vehicle control system of claim 12, wherein the one or more processors are further configured to: determine a current location of the transportation vehicle; plan a travel route from the current location of the transportation vehicle to the container loading location based on the container loading task for the transportation vehicle; determine a sensed result of environment; determine travel decision information based on the sensed result and the travel route; and control the transportation vehicle to move to the container loading location along the travel route based on the travel decision information.
 16. The vehicle control system of claim 12, wherein the one or more processors are further configured to: determine a current location of the transportation vehicle; plan a travel route from the current location of the transportation vehicle to the container unloading location based on the container unloading task for the transportation vehicle; determine a sensed result of environment; determine travel decision information based on the sensed result and the travel route; and control the transportation vehicle to move to the container unloading location along the travel route based on the travel decision information.
 17. The vehicle control system of claim 16, wherein the sensed result comprises at least one of a type, shape, contour, location or distance of an obstacle in the environment.
 18. A method comprising: transmitting ship information and container information to a scheduling center system; and upon receiving a ship berthing task from the scheduling center system, controlling a target ship to move to an operation area corresponding to a target shore crane apparatus; and transmitting a ship in-position notification message to a shore crane control system of the target shore crane apparatus.
 19. The method of claim 18, wherein transmitting the ship in-position notification message to the shore crane control system of the target shore crane apparatus comprises: determining a travel time length from a current location of the target ship to a port based on the current location of the target ship, a location of the port and a travel route; estimating an arrival time at which the target ship arrives at the port based on the travel time length; and transmitting the ship information containing the estimated arrival time and ship state information and the container information to the scheduling center system.
 20. The method of claim 19, further comprising: transmitting the ship information and the container information to the scheduling center system so that the scheduling center system generates the ship berthing task based on the ship information and the container information. 